Carrier priming effect of CRM197 is related to an enhanced B and T cell activation in meningococcal serogroup A conjugate vaccination. Immunological comparison between CRM197 and diphtheria toxoid.

Glycoconjugate vaccines are composed of capsular polysaccharides (CPSs) of a pathogenic bacteria covalently linked to carrier proteins. Pre-exposure to the carrier is known to influence the efficacy of the glycoconjugate, by inducing enhanced or suppressed anti-CPS response. Following our previous work on the immunogenicity of diphtheria toxin mutant CRM197 and formaldehyde-treated diphtheria toxoid (DT) as carriers for meningococcal A (MenA) conjugates in mouse model, we further investigated the role of the carrier on the immunological response to glycoconjugate vaccines. We previously showed that high dosage DT priming could result in carrier-induced epitopic suppression (CIES), an event that did not occur for CRM197 priming, and we observed that anti-DT IgGs could cross-react with DT based conjugates in vitro. Here, we confirmed the cross-reactivity of anti-carrier IgGs with DT conjugates in vivo. Furthermore, we analyzed the splenocytes of animals primed with the carrier and subsequently immunized with the MenA conjugate. Pre-exposure to the carrier protein, both CRM197 and DT, resulted in increased carrier-specific plasma and memory B cell response. However, only for CRM197 priming an enhanced carbohydrate-specific plasma cell response was observed. Analysis of circulating IgGs confirmed these observations. Memory to the CPS resulted to be non-influenced by carrier priming. Analysis of T helper response showed an enhancement effect for CRM197 priming, while DT priming resulted in constrained T cell activation. Stimulation with CRM197, which does not require formaldehyde detoxification, of splenocytes from animal immunized with DT suggested that the formaldehyde treatment used to produce DT might be the cause of limited presentation of the antigen to the T cells. We concluded that the dominant carrier-specific B cell response in case of limited T cell recruitment might explain the previously observed CIES phenomenon in case of DT priming.

Evaluation of the non-toxic mutant of the diphtheria toxin K51E/E148K as carrier protein for meningococcal vaccines.

Diphtheria toxin mutant CRM197 is a common carrier protein for glycoconjugate vaccines, which has been proven an effective protein vector for, among others, meningococcal carbohydrates. The wide-range use of this protein in massive vaccine production requires constant increase of production yields and adaptability to an ever-growing market. Here we compare CRM197 with the alternative diphtheria non-toxic variant DT-K51E/E148K, an inactive mutant that can be produced in the periplasm of Escherichia coli. Biophysical characterization of DT-K51E/E148K suggested high similarity with CRM197, with main differences in their alpha-helical content, and a suitable purity for conjugation and vaccine preparation. Meningococcal serogroup A (MenA) glycoconjugates were synthesized using CRM197 and DT-K51E/E148K as carrier proteins, obtaining the same conjugation yields and comparable biophysical profiles. Mice were then immunized with these CRM197 and DT-K51E/E148K conjugates, and essentially identical immunogenic and protective effects were observed. Overall, our data indicate that DT-K51E/E148K is a readily produced protein that now allows the added flexibility of E. coli production in vaccine development and that can be effectively used as protein carrier for a meningococcal conjugate vaccine.

Carrier priming with CRM 197 or diphtheria toxoid has a different impact on the immunogenicity of the respective glycoconjugates: biophysical and immunochemical interpretation.

Glycoconjugate vaccines play an enormous role in preventing infectious diseases. The main carrier proteins used in commercial conjugate vaccines are the non-toxic mutant of diphtheria toxin (CRM197), diphtheria toxoid (DT) and tetanus toxoid (TT). Modern childhood routine vaccination schedules include the administration of several vaccines simultaneously or in close sequence, increasing the concern that the repeated exposure to conjugates based on these carrier proteins might interfere with the anti-polysaccharide response. Extending previous observations we show here that priming mice with CRM197 or DT does not suppress the response to the carbohydrate moiety of CRM197 meningococcal serogroup A (MenA) conjugates, while priming with DT can suppress the response to DT-MenA conjugates. To explain these findings we made use of biophysical and immunochemical techniques applied mainly to MenA conjugates. Differential scanning calorimetry and circular dichroism data revealed that the CRM197 structure was altered by the chemical conjugation, while DT and the formaldehyde-treated form of CRM197 were less impacted, depending on the degree of glycosylation. Investigating the binding and avidity properties of IgGs induced in mice by non-conjugated carriers, we found that CRM197 induced low levels of anti-carrier antibodies, with decreased avidity for its MenA conjugates and poor binding to DT and respective MenA conjugates. In contrast, DT induced high antibody titers able to bind with comparable avidity both the protein and its conjugates but showing very low avidity for CRM197 and related conjugates. The low intrinsic immunogenicity of CRM197 as compared to DT, the structural modifications induced by glycoconjugation and detoxification processes, resulting in conformational changes in CRM197 and DT epitopes with consequent alteration of the antibody recognition and avidity, might explain the different behavior of CRM197 and DT in a carrier priming context.

Diffusion of meticillin-resistant Staphylococcus aureus USA300 strains in central Italy.

Meticillin-resistant Staphylococcus aureus (MRSA) is an outstanding, clonally evolving pathogen that in recent years, under the selective pressure of antibiotics, has acquired the crucial ability to infect people outside of hospitals. MRSA USA300 has progressively become synonymous with severe community-associated staphylococcal disease worldwide. Whilst spreading worldwide, these clones have progressively acquired resistance to several antibiotics and have gained the ability to cause infections in hospital settings. Recently, USA300-related strains showing resistance to several antibiotics have been isolated from community-acquired infections in Italy. This paper reports the high frequency of isolation of USA300-related strains both from community- and hospital-acquired infections in central Italy as well as their genotypic characteristics and antibiotic susceptibility. Analysis of these characteristics by partial least squares discriminant analysis enabled it to be demonstrated that whilst moving from the community to the hospital setting these isolates underwent an adaptive process that generated clones showing distinctive characteristics. These observations further support the hypothesis that the threatening generation of strains combining both resistance and virulence is becoming a reality, and stress the necessity of constant molecular epidemiological surveillance of MRSA.